KR20130057529A - A serum quick freezer - Google Patents

Abstract

PURPOSE: A plasma deep freezer is provided to improve the heat insulation of a space containing plasma by comprising a heat insulation layer with a first heat insulation material, a heat insulation diaphragm, and a second heat insulation material, to reduce power consumption, and to improve the durability of the heat insulation layer. CONSTITUTION: A plasma deep freezer comprises: a main body with a space containing plasma; and a freezing device which freezes the plasma. The main body comprises: an inner housing(111) forming the space, an outer housing(115) which surrounds the inner housing, and a heat insulation layer(130) placed between the inner housing and the outer housing. The heat insulation layer comprises a first heat insulation material(131), a heat insulation diaphragm(133), and a second heat insulation material(132). The first heat insulation material surrounds the inner housing and is made of urethane. The heat insulation diaphragm surrounds the first heat insulation material. The second heat insulation material surrounds the heat insulation diaphragm and is made of urethane.

Description

Plasma Quick Freezer {A serum quick freezer}

The present invention relates to a plasma quick freezer that can be stored frozen rapidly to prevent alteration of the plasma of the animal.

In general, plasma is a liquid component that subtracts blood cells such as red blood cells, white blood cells, and platelets from blood, and contains 90% water, 7-8% protein (albumin, globulin, fibrinogen, etc.) and other lipids, sugars, inorganic salts and amino acids. And a pale yellow neutral liquid composed of uric acid and the like.

On the other hand, the plasma is stored in a frozen state, the plasma is usually stored for 1 year at -18 ℃ or less, and since plasma is easily deteriorated at room temperature, it must be frozen quickly and quickly to preserve the plasma fresh.

In order to quickly and rapidly freeze such plasma, a "plasma quick freezer" of Korean Patent No. 10-0915427 (Registration Date 2009.08.27) has been disclosed.

The conventional plasma rapid freezer is a refrigerator main body having a vacuum insulation panel attached to the inner wall of the outer case, the freezer body formed of a heat insulating portion between the outer case and the chamber for receiving plasma; And a cooler for cooling the chamber.

Conventional plasma rapid freezer having the above configuration was able to freeze the plasma quickly and quickly by operating the cooler to cool the chamber while the freezer body is insulated.

However, in the conventional plasma rapid freezer, the vacuum insulation panel is installed to insulate the chamber. However, since the thermal insulation of the vacuum insulation panel is not high, the cooler is frequently operated to increase the consumption of electricity.

In addition, complicated steps and equipment are required to form the interior of the vacuum insulation panel into a vacuum, and it is not only difficult to seal the vacuum insulation panel, but also the vacuum insulation panel is easily deformed due to temperature difference and sealed in the vacuum insulation panel. There were problems such as cracking.

The present invention was created to solve the problems described above, the problem to be solved by the present invention is to improve the thermal insulation of the chamber containing the plasma to reduce the consumption of electricity, the thermal insulation layer is easy by the temperature difference It is possible to prevent deformation, and to provide a plasma quick freezer that can reduce the manufacturing cost by configuring the insulating layer in a relatively simple structure.

In the plasma quick freezer according to an embodiment of the present invention to solve the above problems in the plasma rapid freezer comprising a freezing body formed with a receiving space for receiving plasma, and a freezing device for freezing the plasma contained in the receiving space The freezing body includes an inner housing forming the accommodation space, an outer housing surrounding the inner housing, and an insulating layer positioned between the inner housing and the outer housing, wherein the insulating layer surrounds the inner housing and is formed of urethane. It includes a first heat insulating material, a heat insulating plate surrounding the first heat insulating material, and a second heat insulating material formed of urethane surrounding the heat insulating plate.

The insulating plate may be a polycarbonate (PC) panel.

The first heat insulating member may have a plurality of first air grooves formed on a surface of the first heat insulating material in contact with the heat insulating partition, and the first air groove may be sealed by the heat insulating partition to form a sealed insulating layer.

A first adhesive layer may be provided between the heat insulating plate and the first heat insulating material to bond the heat insulating plate and the first heat insulating material to seal the first air groove.

The first air groove may be coated with a sealing material to prevent the flow of air.

The second heat insulating material may have a plurality of second air grooves formed on a surface of the second heat insulating material in contact with the heat insulating partition, and the second air groove may be sealed by the heat insulating partition to form a sealed insulating layer.

A second adhesive layer may be provided between the heat insulating plate and the second heat insulating material to bond the heat insulating plate and the second heat insulating material to seal the second air groove.

The second air groove may be coated with a sealing material to prevent the flow of air.

The sealant may comprise silicon.

The refrigerating device includes a first freezing unit having a refrigeration pipe for freezing the accommodating space by a refrigerant outside the inner housing, and circulating the air in the accommodating space inside the inner housing. The refrigerator may include a second freezing unit.

The second refrigeration unit is a refrigeration housing having a suction port for intake of air in the accommodation space and a discharge port for discharging the air sucked into the suction port, a blowing fan provided in the refrigeration housing to suck and discharge the air in the accommodation space; It may include an evaporator provided in the refrigeration housing for freezing the air sucked into the suction port by the refrigerant.

According to the present invention, the heat insulating layer is composed of the first heat insulating material, the heat insulating plate, and the second heat insulating material to improve the heat insulating property of the accommodation space accommodating the plasma, thereby minimizing the operation of the refrigerating device to reduce the consumption of electricity.

In addition, the insulation plate may support the first heat insulating material and the second heat insulating material to prevent the first heat insulating material and the second heat insulating material from being easily deformed due to the temperature difference, thereby improving durability of the heat insulating layer.

In addition, by constructing a sealed insulation layer with a relatively simple structure, there is an effect that can improve the thermal insulation of the insulation layer and at the same time reduce the manufacturing cost.

1 is a perspective view showing a plasma quick freezer according to an embodiment of the present invention.
Figure 2 is a front sectional view showing a plasma quick freezer according to an embodiment of the present invention.
3 is an enlarged view of a portion “A” of FIG. 2.
Figure 4 is a perspective view schematically showing a heat insulating layer of the plasma quick freezer according to an embodiment of the present invention.
Figure 5 is a side cross-sectional view schematically showing a second freezing portion of the plasma quick freezer according to an embodiment of the present invention.
6 is a view showing a schematic configuration of a refrigeration apparatus constituting a plasma rapid freezer according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 1 and 2, the plasma rapid freezer 100 according to an embodiment of the present invention may include a freezing body (110). The freezing body 110 may be stored in a state in which the accommodating space 113 is formed to freeze the received body fluid.

In addition, a door may be installed in the freezing body 110 to open or close the receiving space 113 to carry in and take out the body fluid into the receiving space 113.

In addition, the freezing body 110 may be provided with an operation panel 117 for operating the plasma rapid freezer 100, the operation panel 117 includes a display for grasping the operation state on the plasma rapid freezer (100). Can be configured.

On the other hand, the freezing body 110 may include an inner housing (111). The inner housing 111 may be formed in a rectangular box shape with one side open, and an accommodation space 113 may be formed in the inner housing 111 to store body fluids.

In this case, the door may be installed on one side of the inner housing 111 to be installed on the freezing body 110 to be easily opened and closed by a hinge to open or close the receiving space 113.

In addition, a plurality of shelves 119 containing body fluids contained in the sealed bag may be installed in the accommodation space 113.

The freezing body 110 may include an outer housing 115. The outer housing 115 forms the exterior of the storage body, and the inner housing 111 may be installed inside the outer housing 115. In addition, a plurality of wheels may be installed at the lower end of the outer housing 115 to easily move the freezing body 110.

As shown in Figure 3 and 4, the freezing body 110 may include a heat insulating layer (130). The insulating layer 130 is located between the inner housing 111 and the outer housing 115 to block heat exchange between the inner housing 111 and the outer housing 115, thereby freezing the accommodating space 113. The fall of efficiency can be prevented.

On the other hand, the heat insulating layer 130 may include a first heat insulating material 131. The first heat insulating material 131 wraps and insulates the inner housing 111, and may be formed of urethane.

In this case, it is preferable that the urethane is foamed urethane having excellent heat insulation by including air therein, and the first heat insulator 131 may be provided to surround all surfaces except for the open portion of the inner housing 111.

A plurality of first air grooves 131a may be formed in the first heat insulating material 131. The first air groove 131a is formed on a surface of the first heat insulating material 131 on which the heat insulating plate 133 is to be described below, so that when the first heat insulating agent is wrapped by the heat insulating plate 133, that is, the first air groove 131a is formed. When the heat insulating plate 133 is attached to the heat insulating material 131, the heat insulating plate 133 may be sealed to form a sealed heat insulating layer.

On the other hand, the first air groove (131a) may be formed in a semi-circular shape, the first air groove (131a) may be coated with a sealing material to prevent the flow of air to improve the sealing degree. Here, the sealing material may be silicone, synthetic rubber, natural rubber, or an adhesive to be described below.

Here, by forming the first air groove 131a for forming the sealed insulating layer in the first heat insulating material 131, heat is blocked by the sealed heat insulating layer, thereby further improving the performance of the heat insulating material.

The heat insulation layer 130 may include a heat insulation partition 133. The heat insulating plate 133 surrounds the first heat insulating material 131 in a plate shape to block heat transmitted to the first heat insulating material 131, and the first heat insulating material 131 and the second heat insulating material 132 are easily changed to the temperature difference. The deformation can be prevented.

On the other hand, the heat insulating plate 133 is formed in a plate shape can wrap the entire first heat insulating material 131, the heat insulating plate 133 is the first using a panel of a material having a higher density than the first heat insulating material 131. It is possible to block heat from being transferred to the heat insulator 131.

In addition, the heat insulating plate 133 is formed of a material that is relatively rigid than the first heat insulating material 131 and the second heat insulating material 132 to support the first heat insulating material 131 and the second heat insulating material 132, thereby providing a first heat insulating material. It is possible to prevent the heat insulating material 131 and the second heat insulating material 132 from being easily deformed by the temperature difference.

Here, the heat insulating plate 133 is preferably a polycarbonate panel formed of polycarbonate (PC), which is relatively higher than other materials having heat insulating properties and durability.

The heat insulating plate 133 may seal the first air groove 131a formed in the first heat insulating material 131 to form a sealed heat insulating layer.

In addition, a first adhesive layer 134 may be provided between the heat insulating plate 133 and the first heat insulating material 131. The first adhesive layer 134 bonds the heat insulating plate 133 and the first heat insulating material 131 to each other and seals a portion where the heat insulating plate 133 and the first heat insulating material 131 contact each other to form a first air groove 131 a. ) Can further improve the sealing degree.

On the other hand, the first adhesive layer 134 may be implemented as an adhesive for bonding the heat insulating plate 133 and the first heat insulating material 131, the adhesive is an airtightness between the first adhesive layer 134 and the heat insulating plate 133. Silicon may be included to enhance.

Here, the sealing material coated on the first air groove 131a may be implemented in a form in which an adhesive constituting the first adhesive layer 134 is applied.

The heat insulation layer 130 may include a second heat insulator 132. The second heat insulator 132 wraps the heat insulating plate 133, and wraps the heat insulating plate 133 surrounding the first heat insulating material 131, thereby preventing heat from being transferred to the heat insulating plate 133 to provide a heat insulating effect. It can be further improved.

On the other hand, the second heat insulator 132 may be formed of the same urethane as the first heat insulator 131, in this case, it is preferable that the urethane is a foamed urethane having excellent heat insulating properties including air therein.

In addition, a plurality of second air grooves 132a may be formed in the second heat insulating material 132. The first air groove 131a is formed on the surface of the second heat insulating material 132 in contact with the heat insulating plate 133 to be described below, so that when the second heat insulating material 132 surrounds the heat insulating plate 133, that is, When the second heat insulating material 132 is attached to the heat insulating plate 133, the second heat insulating material 132 may be sealed to form a sealed heat insulating layer.

On the other hand, the second air groove (132a) may be formed in a semi-circular shape, the second air groove (132a) may be coated with a sealing material to prevent the flow of air to improve the sealing degree.

In addition, the second air groove 132a may be formed to overlap only part of the first air groove 131a at different positions, not at positions corresponding to each other.

In addition, a second adhesive layer 135 may be provided between the heat insulating plate 133 and the second heat insulating material 132. The second adhesive layer 135 bonds the heat insulating plate 133 and the second heat insulating material 132 to each other and seals a portion where the heat insulating plate 133 and the second heat insulating material 132 contact each other to form a second air groove 132a. ) Can further improve the sealing degree.

On the other hand, the second adhesive layer 135 may be implemented as an adhesive for bonding the heat insulating plate 133 and the second heat insulating material 132, the adhesive is the airtightness between the second adhesive layer 135 and the heat insulating plate 133. Silicon may be included to enhance.

Here, the sealing material coated on the second air groove 132a may be implemented in a form in which an adhesive constituting the second adhesive layer 135 is applied.

As shown in Figures 2, 5 and 6, the plasma quick freezer 100 according to an embodiment of the present invention may include a freezing device (150). The freezing device 150 may freeze the body fluid located in the accommodation space 113 by freezing the accommodation space 113.

Meanwhile, the refrigerating device 150 may include a first freezing unit 151 and a second freezing unit 156.

The first freezing unit 151 may be located outside the inner housing 111 with respect to the inner housing 111 to freeze the accommodating space 113 in a form of heat exchange with the inner housing 111.

Meanwhile, the first freezing unit 151 may include a freezing pipe 152. The refrigeration pipe 152 may freeze the internal housing 111 in a form in which a refrigerant, for example, a freon gas, exchanges heat with the internal housing 111 through the inside of the refrigeration pipe 152.

In this case, the refrigeration pipe 152 is provided on the outer surface of the inner housing 111 to surround the entire of the inner housing 111 in a zigzag form so that the refrigeration pipe 152 exchanges heat with the inner housing 111. (113) can be frozen.

The first refrigeration unit 151 may further include a compressor 153, a condenser 154, and an expansion valve 155 that operate the refrigeration pipe 152.

The compressor 153 recovers and compresses the refrigerant passing through the refrigeration pipe 152 and sends the compressed refrigerant to the condenser 154. The condenser 154 liquefies the refrigerant, and the liquefied refrigerant is supplied to the refrigeration pipe 152 by lowering the pressure through the expansion valve 155. The refrigeration pipe 152 is frozen in a form in which the refrigerant having a lowered pressure expands and takes heat away from the surroundings. Since the operation of the first freezing unit 151 is a known technique, more detailed description thereof will be omitted.

 The second freezing unit 156 is installed on the inner surface of the inner housing 111, more specifically, on the upper surface of the receiving space 113 to receive heat in the form of freezing the receiving space 113 by exchanging heat with air in the receiving space 113. The space 113 can be frozen rapidly.

Meanwhile, the second freezing unit 156 may include a freezing housing 157, a blowing fan 158, and an evaporator 159.

The refrigeration housing 157 is installed in the accommodation space 113 so that the air in the accommodation space 113 is sucked into the inside of the refrigeration housing 157 and the inlet flows into the freezing housing 157. An outlet 157b for discharging air back to the accommodation space 113 may be formed.

The blowing fan 158 is installed inside the freezing housing 157 to suck the air in the accommodation space 113 through the inlet 157a of the freezing housing 157 and discharge the sucked air to the outlet 157b. The air in the accommodation space 113 can be circulated.

The evaporator 159 may be installed inside the freezing housing 157 to freeze the air sucked into the inlet 157a of the freezing housing 157 to a lower temperature.

On the other hand, the evaporator 159 may further lower the temperature of the air in the accommodation space 113 in the form that the refrigerant passing through the evaporator 159 expands and takes heat away.

Here, the second freezing unit 156 may further include a compressor 153, a condenser 154, and an expansion valve 155 that operate the evaporator 159.

The compressor 153 recovers and compresses the refrigerant passing through the evaporator 159, and sends the compressed refrigerant to the condenser 154. The condenser 154 liquefies the refrigerant, and the liquefied refrigerant is supplied to the evaporator 159 by lowering the pressure through the expansion valve 155. The evaporator 159 is frozen in a form in which the refrigerant whose pressure is lowered expands and takes heat away from the surroundings. Since operation of the second refrigeration unit 156 is a known technique, more detailed description thereof will be omitted.

On the other hand, the refrigeration pipe 152 of the first refrigeration unit 151 and the evaporator 159 of the second refrigeration unit 156 is one compressor 153, the condenser 154, and the expansion valve 155 as in the embodiment. Or a refrigerant 153 is supplied together with the refrigerant (see FIG. 6), or the compressor 153 is provided to each of the evaporator 159 of the refrigeration pipe 152 of the first refrigeration unit 151 and the second refrigeration unit 156. ), The condenser 154, and the expansion valve 155 may be configured to supply the refrigerant separately.

The operation and effect between the above-described respective constitutions will be described.

The plasma rapid freezer 100 according to the embodiment of the present invention opens the door and closes the door in a state where the body fluid contained in the sealed bag is stored in the shelf 119 of the accommodation space 113 to seal the accommodation space 113. do.

The first freezing unit 151 is operated to freeze the accommodating space 113, and the second freezing unit 156 is also operated to rapidly freeze the body fluid in a form of directly freezing the air in the accommodating space 113.

At this time, the second refrigeration unit 156 stops the operation when the temperature is arbitrarily set below, and only the first refrigeration unit 151 is operated to keep the temperature of the accommodation space 113 constant.

Here, the insulating layer 130 is provided between the inner housing 111 and the outer housing 115 forming the accommodation space 113 can maintain the temperature of the accommodation space 113 for a long time.

On the other hand, the heat insulating layer 130 is the first heat insulating material 131 and the heat insulating plate 133 so that the adhesive is formed by the adhesive layer in a state where the heat insulating plate 133 is located between the first heat insulating material 131 and the second heat insulating material 132. ) And between the second heat insulating material 132 and the heat insulating plate 133 to insulate between the inner housing 111 and the outer housing 115.

At this time, the first air groove 131a of the first heat insulating material 131 and the second air groove 132a of the second heat insulating material 132 are tightly sealed to the heat insulating plate 133, whereby the first air groove 131a is closed. And the air insulation layer is formed in the second air groove (132a) can further improve the thermal insulation of the heat insulating layer (130).

As a result of the test of the plasma rapid freezer 100 having the thermal insulation layer 130 configured as described above, the first freezing unit 151 and the second freezing unit 156 at the temperature of the receiving space 113 at -80 ° C. When the operation was stopped, the temperature was maintained for 30 minutes, and when the first refrigeration unit 151 and the second freezing unit 156 was stopped at -40 ° C, the temperature was maintained for 40 minutes.

Therefore, the plasma quick freezer 100 according to the embodiment of the present invention may have excellent thermal insulation and may reduce electricity consumption of the plasma rapid freezer 100, and the thermal insulation plate 133 may be installed to provide rigidity of the thermal insulation layer 130. In addition, the insulation plate 133 is made of a relatively inexpensive polycarbonate (PC) panel, and the air insulation layer of the first air groove and the second air groove is easily formed to greatly improve the thermal insulation performance of the plasma rapid freezer. At the same time, there is an effect that can reduce the production cost.

Therefore, the plasma rapid freezer 100 according to the embodiment of the present invention may have excellent thermal insulation property, thereby minimizing the electricity consumption of the plasma rapid freezer 100, and the thermal insulation plate 133 may be installed to provide rigidity of the thermal insulation layer 130. In addition, the insulation plate 133 may be made of a polycarbonate (PC) panel, and the manufacturing cost may be greatly reduced by eliminating the use of a vacuum panel.

While the present invention has been particularly shown and described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: plasma quick freezer 110: frozen body
111: internal housing 113: accommodation space
115: outer housing 117: operation panel
119: shelf 130: insulation layer
131: first insulation 131a: first air groove
132: second heat insulating material 132a: second air groove
133: heat insulating plate 134: first adhesive layer
135: second adhesive layer 150: refrigeration apparatus
151: first refrigeration unit 152: refrigeration pipe
153: compressor 154: condenser
155: expansion valve 156: second freezing unit
157: freezing housing 157a: inlet
157b: outlet 158: blowing fan
159: evaporator

Claims (11)

In the plasma quick freezer comprising a freezing body having a receiving space for receiving plasma, and a freezing device for freezing the plasma contained in the receiving space,
The frozen body is
An inner housing forming the accommodation space;
An outer housing surrounding the inner housing, and
Including a heat insulation layer located between the inner housing and the outer housing,
The heat insulation layer
A first heat insulating material surrounding the inner housing and formed of urethane,
An insulating plate surrounding the first insulating material, and
And a second heat insulating material formed of urethane surrounding the heat insulating partition plate. The method of claim 1,
The insulation plate is
A plasma quick freezer, characterized in that the polycarbonate (PC) panel. The method of claim 1,
The first heat insulating material
And a plurality of first air grooves are formed on a surface of the first heat insulating material in contact with the heat insulating partition, and the first air grooves are sealed by the heat insulating partition to form a sealed insulation layer. The method of claim 3,
Between the heat insulating plate and the first heat insulating material
And a first adhesive layer for adhering the heat insulating plate and the first heat insulating material to seal the first air groove. The method of claim 3,
In the first air groove
A plasma quick freezer, characterized in that the coating is sealed to prevent the flow of air. The method of claim 1,
The second heat insulator
And a plurality of second air grooves are formed on a surface of the second heat insulating material in contact with the heat insulating partition, and the second air grooves are sealed by the heat insulating partition to form a sealed heat insulating layer. The method according to claim 6,
Between the heat insulating plate and the second heat insulating material
And a second adhesive layer for adhering the heat insulating plate and the second heat insulating material to seal the second air groove. The method according to claim 6,
In the second air groove
A plasma quick freezer, characterized in that the coating is sealed to prevent the flow of air. 9. The method according to claim 5 or 8,
The sealant
A plasma quick freezer comprising silicon. The method of claim 1,
The freezing device
A first refrigeration unit having a refrigeration pipe for freezing the accommodation space by a coolant outside the inner housing;
And a second freezing unit configured to freeze the accommodation space in a form in which air in the accommodation space is circulated inside the inner housing. The method of claim 10,
The second freezing unit
A freezing housing having an intake port through which the air in the accommodation space is sucked and an outlet port for discharging the air sucked into the intake port,
A blowing fan provided in the refrigeration housing for sucking and discharging air in the accommodation space;
And a vapor evaporator provided in the freezing housing to freeze the air sucked into the suction port by the refrigerant.

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